JP4053986B2 - Spindle sleeve with responder - Google Patents

Description

  The present invention relates to a spindle sleeve having a responder, and more particularly to a spindle sleeve having a pocket for receiving the responder without being fixed.

  Various spinning materials including glass fibers are manufactured in a spinning process. The fiber is spun and wound on a spindle. The spindle is generally a cylinder made of cardboard.

  What is needed in the manufacturing process is to write some information to each spindle as soon as the manufacturing process is finished. This makes it possible to identify and detect the glass fibers on each spindle.

  In general, information is visually written to each spindle for reading by a person or bar code reader.

  Information can be written and read by other non-visual means. For example, it may be possible to mold the transponder in the product. The responder accumulates and transmits information in response to a user request. The answering machine is typically interrogated by the caller when the stored information is needed.

  A typical prior art is US Pat. No. 5,028,918 (1991) to Giles et al., Which can respond to a response command signal and is unique to each individual. A transponder circuit, which may be a passive circuit capable of transmitting the identification code, is disclosed.

  Further, a typical prior art is European Patent Publication No. 956537 of PAV Card GmbH, which includes a transmission module for data transmission between a transmitter and a reader that can be operated remotely. Is disclosed.

  Also, a typical prior art is Wibmer GmbH, WO 99/23024, which discloses a wound sleeve having a plurality of layers connected to each other, A cut is provided in the inner layer, and a responder is embedded in the cut, and the majority of the responder is at least almost the same as an elongated piece cut so as to avoid inconsistencies between the sleeve and the responder. is there.

  However, prior art responders are molded into the product. Therefore, mechanical damage is likely to be caused by strain transmitted to the responder caused by bending of the product. Repeated flexing of the responder in use causes premature failure.

  What is needed is a spindle sleeve with electrical data processing means. What is required is a spindle sleeve with a responder for receiving and transmitting data. What is needed is a spindle sleeve with a sealable pocket to accommodate the transponder. What is required is a spindle sleeve having means for accommodating the transponder without deflection. What is needed is a spindle sleeve with a sealable pocket that lies radially outward from the tensile cord to reduce the transmitted strain. The present invention meets these requirements.

  The main object of the present invention is to provide a spindle sleeve having electrical data processing means.

  Another object of the present invention is to provide a spindle sleeve having a responder for data reception and transmission.

  Another object of the present invention is to provide a spindle sleeve having a sealable pocket for receiving a transponder.

  Another object of the present invention is to provide a spindle sleeve having means for retracting the responder so as not to bend.

  Another object of the present invention is a spindle sleeve having a sealable pocket positioned to radiate outwardly from the tensile cord in order to reduce the transmitted strain.

  Other objects of the present invention will be clarified or pointed out by the following description of the invention and the accompanying drawings.

The present invention includes a transponder that is movably fitted into a pocket on an elastomeric spindle sleeve. The pocket has a plastic joint formed in the sleeve during curing or vulcanization. When the sleeve has been cured or vulcanized, the responder is inserted into the pocket. The open end of the pocket is sealed with an adhesive. During manufacturing, the transponder will not be molded into the pocket or fixed in the pocket, so it will move inside the pocket. This can minimize the strain that would be transmitted to the responder while the sleeve is flexing, thereby extending the life of the responder. The transponder receives, accumulates, and transmits manufacturing data via a hand-held or fixed electrical device. The transponder has a microchip and antenna in addition to the plastic or paper laminate to which it is attached. Since the transponder is activated by RF (radio frequency) energy received from the antenna, no battery is required.

  The accompanying drawings are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention, and provide a description of the nature of the invention together with the detailed description.

  FIG. 1 is a perspective view of a responder in a sleeve pocket. The responder 200 includes a micro processing device 201 connected to the coil antenna 202. The responder and antenna are enclosed in a pocket 101 formed in the elastomer sleeve 100. The sleeve is used, for example, in a spinning machine.

  The sleeve 100 is made by a method known as an elastomer belt manufacturing technique, i.e., a continuous layer of elastomer is laminated onto a build mandrel (not shown). During manufacture, a single piece of polyester plastic 102 is placed between the elastomeric layers. The piece 102 is made of a woven or non-woven material depending on the operating temperature. The tensile core is also wound around the sleeve build as shown in FIG. The sleeve is manufactured by winding a tensile cord in the longitudinal direction in order to resist centrifugal force generated in the spinning process. The sleeve may experience a rotational speed of 5000 rpm or higher. The tensile core will be composed of polyester, glass fiber, nylon 6.6, nylon 4.6, aramid, cotton, and equivalent materials known in the art. The build-up belt is cured or vulcanized by applying heat and pressure. The vulcanized slab will be cut into individual sleeves.

  Piece 102 is formed into a thin layer between successive elastomeric layers to form a hollow with a receiving member or pocket 101. Piece 102 prevents adjacent elastomer layers from joining across the piece. As shown in FIG. 4, the pieces 102 are disposed radially between the tensile cord and the outer elastomer layer 105 of the cord, outside the tensile cord. This is to prevent the responder from being crushed between the spinner mandrel and the tensile cord when attaching the sleeve to the spinning machine as shown in FIG. Piece 102 is a non-metallic material that bonds only to a single face of the elastomer during curing or vulcanization. This ensures that the storage pocket is formed during curing or vulcanization without the elastomeric layer being bonded. Furthermore, piece 102 is non-metallic so as not to interfere with RF signals received by and transmitted from the responder antenna. Alternatively, piece 102 is removed from the sleeve as soon as the transponder is inserted after curing or vulcanization to provide a suitable final sleeve thickness t as shown in FIG. Also good. The thickness of the various pieces 102 will be used to achieve an appropriate final sleeve thickness.

  Alternatively, when the responder is inserted into the pocket, a portion of the elastomeric layer that encases the pocket is omitted during manufacture in order to achieve an appropriate constant final thickness of the entire circumference. Thus, the thickness of the responder may be added to the piece 102.

  As soon as vulcanization or curing is complete, the belt builds are cut into appropriate widths, each having a pocket 101. The responder 200 is inserted into the pocket 101. When the responder 200 is inserted, the open end 111 of the pocket is hermetically sealed using a suitable adhesive, such as cyan acrylate or other equivalent.

  The open end of the pocket is enclosed and closed, but the responder 200 is not fixed to the pocket. Instead, the responder 200 moves freely within the enclosed pocket to minimize strain transmitted to the responder by flexing of the sleeve during removal from the spinning machine or removal from the glass coil, or lose.

  FIG. 2 is a plan view of the responder. The responder 200 is a passive circuit having no internal power supply source. The responder receives a radio frequency (RF) or clock signal from the interrogator. It accumulates the voltage from the input signal that passes through the coil antenna 202. The responder 202 uses the voltage accumulated from the transmitted signal to supply power to the processing device 201, which reads the memory and sends an appropriate response to the interrogator.

The responder of the above-mentioned aspect is conventionally known. For example, without limitation, suitable responders are manufactured by German PAV Card Corporation. A specific product is PAV model number 16A-MIR. Processor 201 and coil antenna 202 are laminated on a plastic material 203 is flexible and durable. The overall thickness of the laminated transponder is less than 1 mm. This form of transponder is very thin, highly wear resistant and is particularly suitable for applications where the total thickness of the sleeve is limited to a maximum of approximately 3 mm. This example does not represent a means limitation, and any equivalent responder plays a similar role. Material 203 is non-metallic so as not to interfere with the RF signal.

  FIG. 3 is a perspective view of a part of the spinning machine including the sleeve of the present invention. In use, a rubber sleeve with a responder is attached to a spinning machine for spinning glass fibers, for example. The spinning machine has a mandrel member on which a coil is wound, as partially shown in FIG. The depiction of the mandrel member M shown in FIG. 3 is an example for the purpose of explanation, and is not shown to limit the shape or aspect of the spinning machine in particular. The mandrel protrusion M is generally cylindrical. The mandrel member is operated by a spinning machine in a manner known in the art. The sleeve of the present invention generally has a belt-like shape when placed on a mandrel member.

  The spun material is spun onto the sleeve during manufacture. When the fiber coil is placed on the sleeve, the mandrel member M is folded inward and removed from the inner diameter of the sleeve. The coil is left on the flexible sleeve throughout the handling and unloading. As soon as the coil is received by the user, the responder is read. The flexible sleeve is folded inside and removed from the glass fiber coil. This results in a number of savings in methods that require a spindle, such as a cardboard spindle, that must be used for each glass fiber coil and discarded after one or several uses. Unlike the cardboard spindle, the sleeve of the present invention is reused by the manufacturer, and the number of uses is limited only by the durability of the sleeve itself.

  In operation, manufacturing information regarding the material wound on the sleeve is determined by the user before or during the spinning operation. That information is loaded into the transmitter. The transmitter sends the information to the responder in the sleeve. Information is stored in the memory unit of the responder.

  At the point of use, the interrogator queries the responder in the sleeve. In response to the interrogation signal, the transponder transmits information that is loaded during manufacture, particularly about the material wrapped around the sleeve. The responder is read without using any visual reader, such as a bar code reader. It should be noted that the responder's processor can read / write, thereby allowing the sleeve to be used repeatedly.

  4 is a cross-sectional view of the sleeve of the present invention taken along 4-4 in FIG. The transponder 200 is placed in the pocket 101 as shown. The pocket 101 is formed by a piece 102 between the elastomer layer 105 and the tensile cord 107. The elastomer layer 108 is a layer below the core wire. The sleeve may have a tooth-shaped cross section 109 as shown in FIG. 5, which can enhance the engagement between the sleeve and the mandrel member. The sleeve does not have to have a tooth profile, and may have a tooth profile on the opposite side shown in FIG.

  Although one aspect of the invention has been described herein, it will be apparent that variations in certain constructions and relationships may be made by those skilled in the art without departing from the spirit or scope of the invention.

It is a perspective view of the responder in a sleeve pocket. It is a top view of a responding machine. It is a perspective view of a part of a mandrel of a spinning machine including a sleeve of the present invention. FIG. 6 is a cross-sectional view of the sleeve of the present invention taken along 4-4 in FIG. It is sectional drawing of the tooth | gear of a sleeve.

Claims (18)

An elastomer product having a housing member therein and cured in the vulcanization process;
A transponder circuit comprising a processing device and a signal antenna for exchanging information with an electrical device for remote operation;
With
The circuit of the responder is enclosed in the housing member,
The data system according to claim 1, wherein the housing member is a pocket formed by joining only one surface of the piece to the elastomer in the vulcanization process.   The data system of claim 1, further comprising an interrogator unit for signaling the responder for the responder to receive or transmit product information.   A memory unit for storing product information, a receiver for receiving a signal from an interrogator, and a transmitter for calling and transmitting information stored in the memory unit The data system according to claim 1, further comprising:   The data system according to claim 1, wherein the responder is sealed in the housing member with an adhesive.   The data system of claim 1, wherein the piece is flexible and is composed of a non-metallic material. An elastomer body;
A housing member formed on the elastomer body,
The receiving member has a suitable shape for receiving an electrical data automatic recording device;
The electrical data automatic recording device includes a responder movably enclosed in a pocket in the housing member after vulcanization of the elastomer body, and the responder includes a data receiver and A sleeve comprising a data storage unit and a data transmission unit.   The sleeve according to claim 6, wherein the housing member is made of a material suitable only for bonding to the elastomer. It said pocket, the sleeve of claim 6 in which only one surface of the piece in the vulcanization of the elastomer body, characterized in that it is formed by being joined to the elastomeric body. The data system according to claim 1, wherein the circuit of the responder is movable in the housing member.   The sleeve according to claim 6, wherein the responder has a thickness of less than 1 mm.   The sleeve according to claim 6, further comprising a core wire wound in a longitudinal direction in the elastomer body.   The sleeve according to claim 6, wherein the housing member is sealable.   The sleeve according to claim 11, wherein the housing member is radially outside the core wire.   The sleeve according to claim 13, wherein the sleeve has a tooth-shaped cross section. Using a sleeve having a sealed pocket for an electrical data logger to be movably inserted;
Transmitting data to the electrical data automatic recording device as part of a winding process for forming a spinning material coil;
Receiving data from the electrical data automatic recording device,
The sleeve has an elastomer body which is cured in a vulcanization process;
The said pocket is formed by joining only one side of a piece to an elastomer in a vulcanization process, The manufacturing method of the spun material characterized by the above-mentioned.   The method according to claim 15, further comprising storing data in a memory unit of the electrical data automatic recording apparatus.   The method of claim 16, further comprising removing the sleeve from the spinning coil. The method of claim 15 logger of the electrical data attached to a flexible non-metallic material, characterized in Rukoto locked movably sealed in the pocket.

Images